WO1984004964A1 - Device for dosing fluids - Google Patents

Abstract

Pneumatically operated fluid dosing device comprising a dosing vessel (14) arranged within a filling vessel (15) which is provided at its upper portion with an inlet opening (16) and an aeration pipe (17), and at its lower portion with a dosing tube (1) with the outlet (11), the filling vessel (15) being connected at the bottom to a regulation vessel (6), the liquid height (61) being regulated by a level indicator (110); a control unit (130) is connected to a compressed air source (7) which is associated by an air diffuser (8) to a tank (3) opening out by a supply pipe (100) into the regulation vessel (6); the diffusion nozzle (812) of the air diffuser (8) is driven by a driving mechanism (140) towards the stator of the air diffuser (8) by a reference channel and outlets; the air diffuser (8) opens out by one of its outlets to the open air, is connected by another outlet to the compressed air conduit (9), by another outlet by a connection (42) to a plunger tube (51) of an over-pressure regulator (5) and by another connection (41) to the filling vessel.

Description

 Device for dosing liquids 1. The invention relates to a device for dosing liquids, from which a liquid is dosed by a pneumatic action.

The increasing technical requirements in process automation, in chemistry and related industries, as well as in apparatus construction etc. have led to the construction of a whole series of dosing devices that work with the help of a pneumatic action. These devices are characterized by simplicity, accuracy and low susceptibility to interference.

The dosing devices known to date often require complicated devices for stabilizing the internal liquid level, sometimes have to be filled by hand with the liquid to be dosed before the first start-up or when switched on after a long standstill, air bubbles often form even when these devices are filled, that impair the dosing accuracy and the function. The reservoirs of the liquids to be dosed are often limited in size and mostly cannot be placed below these devices. Checking the fill level of the reservoirs often requires complicated Facilities

The necessary air distributors for metering devices require various devices for distributing the auxiliary pressure media. For this purpose, mainly electromagnetic, pneumatic and other controlled systems such as valves, cam discs and similar devices are used. These devices have a relatively large number of mechanical parts, seals, etc., which wear out relatively quickly and are therefore prone to failure, demanding maintenance and cost-intensive. The variety of the individual mechanical parts required, the distribution devices known to date, also has an impact on the size of these devices.

The invention has for its object to eliminate the above-mentioned shortcomings.

This is achieved according to the invention by the measures specified in the characterizing parts of claims 1 to H.

The essence of the invention is described below with reference to exemplary embodiments schematically illustrated in the drawings.

Show it:

Fig. 1: The dosing device in a schematic overall view.

Fig. 2: The metering device in the version with a built-in level sensor Fig 3: The dosing device with a liquid switch

Fig 4: The modified reservoir of the liquid to be dosed for removal from a flow channel or a. container

Fig 5: A variant of the modified reservoir with a check valve or check valve

Fig. 6: An air distributor in an overall schematic representation

Fig. 7: An example of the design of the actual distributor with a rotating distribution nozzle

Fig. 8: An example of the distributor with a straight movement of the distributor nozzle

Fig. 9: Variant of the design of the distribution nozzle and extraction channels with an ejector effect

Figure 1 shows the dosing device in a schematic overall view.

The dosing device shown consists of a Dosing tube 1, which has an upper bend 12 at the top with a mouth 11 open in a free atmosphere and a lower bend 13 at the bottom. A metering vessel 14 is arranged above the lower bend 13 on the side opposite the mouth 11 in such a way that it lies below the mouth 11. The volume of the dosing vessel 14 determines the amount that the dosing device doses. The metering vessel 14 has an inflow opening 16 in its upper part and tapers above this inflow opening 16 into a ventilation pipe 17. The metering vessel 1 4 and its vent pipe 17 are in a filling vessel 15. The lower part of the filling vessel 15 is connected to the inflow pipe 2 with the inflow mouth 21. The inflow pipe 2 has a lower bend 22 at the bottom and opens with its connecting part 23 into the bottom of the regulating vessel 6. The control vessel 6 is placed in such a way that its bottom lies below the inflow mouth 21. The lower bend 22 of the inflow pipe 2 is arranged so deep that the liquid accumulated in the inflow pipe 2 forms a liquid barrier for the maximum overpressure required in the metering device. The control vessel 6 has further inserted a feed pipe 100 with the upper part 101 into its base and is equipped at the top with a preferential run 62 which opens into the drain 63. The suction part of the overflow 62 is placed in such a way that it lies below the upper bend 12 of the metering tube 1. The liquid level is regulated in the control vessel 6; for this purpose, a level sensor 110 is accommodated at the level of the regulated liquid level 61. The regulated liquid level 61 lies below the upper bend 12 of the metering tube 1, below the opening of the ventilation tube 17, below the overflow 62, below the branch 41, the connecting tube 4 and above the inflow opening 16 of the metering tube 1. The feed tube 100 is in the reservoir 3 of the liquid D to be metered, which is below the floor level of the control vessel 6, introduced through the sealed passage 33. The reservoir 3 may be filled with the liquid D to be dosed at a maximum to the upper level 32. The lower part 102 of the feed pipe 100 lies below the lower level 31 of the liquid D to be metered. The compressed air connection 34 arranged in the upper part of the reservoir 3 is connected to the outlet 802 of the air distributor 8 by means of a compressed air line 9. The outlet 801 of the air distributor 8 opens into the free atmosphere, the outlet 803 is connected to the branch 43 of the connecting pipe 4. The branch 42 of the connecting tube 4 is connected to the dip tube 51 of an overpressure regulator 5. In one possible embodiment, the pressure regulator 2 consists of an open vessel 52 which is filled with an auxiliary liquid P and a dip tube 51 with the immersion depth A. The connecting pipe 4 is connected to the upper part of the filling vessel 15 via the branch 41. The compressed air distribution required for the function of the metering device is carried out with the aid of the distribution nozzle 812 of the air distributor 8, which is connected to the compressed air source 7 via the feed line 71. The feed line 71 is further connected to the pressure indicator 72, from which a signal line 134 leads to the control unit 130. The distribution nozzle 812 of the air distributor 8 is by means of the

Drive 140 moves via the clutch 141. The control unit 130 of the entire dosing device controls the drive 140 via the control line 132 and the compressed air source 7 via the control line 133. The level sensor 110 is connected to the control unit 130 by means of a signal line 111 via the transmitter 120 and the line 131. The dosing device in the embodiment according to FIG. 1 works as follows:

Before the first start-up, the metering tube 1, the inflow tube 2 and the control vessel 6 are empty. The reservoir 3 and the pressure regulator 5 are filled with the corresponding liquids (D and P). At the beginning, all of the inner spaces of the discharge tube 1, the filling vessel 15, the inflow tube 2, the connecting tube 4 and also the space above the liquid D to be metered are connected in part directly to the free atmosphere, in part via the air distributor 8.

After switching on the dosing device, the distribution nozzle 812 of the air distributor 8 is positioned by the control unit 130 by means of the drive 140 via the coupling 141 with respect to the outlet 802. After this positioning of the distributing nozzle 812, the control unit 130 then switches on the compressed air source 7. The overpressure generated by the compressed air source 7 now enters the room via the feed line 71, the distribution nozzle 812, the outlet 802. The compressed air line 9 and the compressed air connection 34 of the reservoir 3 above the liquid to be dosed D).

The air pressure source 7 supplies the excess pressure in such a range that, when the liquid D in the reservoir 3 is at a level between the upper level 32 and the lower level 31, a secure filling of the metering device is ensured up to the level of the regulated liquid level 61.

The overpressure required for the delivery of the liquid D from the reservoir 3 to the regulated liquid level 61 is inversely proportional to the liquid level in the reservoir 3. This fact is used to check the liquid level in the reservoir 3 with the aid of the pressure indicator 72.

In the case of an empty reservoir 3 or at a level below the lower mirror level 31, the delivered excess pressure practically drops to zero, which can be evaluated by means of the pressure indicator 72 for alarm output.

The liquid D is pressed into the control vessel 6 by the excess pressure from the reservoir 3 via the feed pipe 100. The control vessel 6 and the filling vessel 15 connected to it by the inflow tube 2 are filled with the liquid D. When the level of the liquid D in the filling vessel 15 has reached the level of the inflow opening 16 of the dosing vessel 14, the dosing vessel 14 and thus also the dosing tube 1 are also filled. The in the dosing 14 penetrating liquid D presses the air inside the metering vessel 14 on the one hand via the metering pipe 1 and the mouth 11, on the other hand via the vent pipe 17, the branch 41, the connecting pipe 4. and the outlets 803 and 801 of the air distributor 8 into the free atmosphere. This prevents the formation of air bubbles.

The filling process lasts until the level of the liquid D in the control vessel 6, the filling vessel 15 and the metering tube 1 with its parts (metering vessel 14, vent tube 17) has reached the level of the regulated liquid level 61.

After reaching the regulated liquid level 61, the control unit 130 is excited by the level sensor 110 via the signal line 111, the transmitter 120 and the line 131 in such a way that the control unit 130 switches off the compressed air source 2 via the control line 133 and. then controls the drive 140 via the control line 132 such that the distribution nozzle 812 of the air distributor 8 assumes a position such that the outputs 802 and 893 are connected to the free atmosphere via the output 801. The compressed air during the filling process in the compressed air line 9 and the reservoir 3 can thus escape into the free atmosphere. This results in a backflow of the liquid D from the control vessel 6, the filling vessel 15, the vent tube 12, the metering vessel 14, the metering tube 1 and the inflow tube 2 into the reservoir 3. After the filling vessel 15 has been completely emptied, the metering vessel 14 remains filled up to the level of the inflow opening 16; this also applies to the other side of the metering tube 1.

After the control vessel 6 has been completely emptied, the inflow pipe 2 remains filled with the liquid D up to the level of the mouth of its connecting part 23 into the control vessel 6, which liquid forms a liquid supply necessary for the further functioning of the metering device.

After the automatic stabilization of the internal liquid levels, as described above, the distributor nozzle 812 of the air distributor 8 is positioned opposite the outlet 803. The compressed air source 2 is then switched on. The compressed air generated by the compressed air source 2 thus penetrates into the connecting pipe 4 via the feed line 71, the distribution nozzle 812 and the outlet 803. The compressed air penetrates through the branch 42 of the connecting pipe 4 into the immersion pipe 51 of the overpressure regulator 5 and, after reaching the corresponding size, bubbles through the auxiliary liquid P into the free atmosphere. The effect of the overpressure regulator 5 results in a regulated overpressure, the size of which is given by the immersion depth A of the immersion tube 51 and by the specific weight of the auxiliary liquid P. The pressure regulator can also be designed in the form of a membrane regulator, float regulator, etc.

The regulated excess pressure acts via the branch 41 of the connecting tube 4 on the in the metering vessel 14 of the metering tube 1 accumulated liquid D and also on the liquid in the inflow pipe 2, which forms a liquid barrier for the excess pressure. As a result, a better amount of the accumulated liquid D is pressed out of the dosing vessel 14 via the mouth 11 of the dosing tube 1. The desired amount of liquid D squeezed out is given by the volume of the metering vessel 14 and by the regulated overpressure that has been set.

FIG. 2 shows an embodiment of the metering device in which the level sensor 110 is accommodated directly in the filling vessel 15. In this embodiment, the connecting part 23 of the inflow pipe 2 is connected directly as a branch to the feed pipe 100, the connecting part 23 being placed below the inflow mouth 21 and the upper part 101 of the feed pipe 100 lying above the regulated liquid level 61 and being equipped with an overflow 62 is. The dosing device according to FIG. 2 works identically to the device according to FIG. 1.

FIG. 3 shows an alternative embodiment of the dosing device with the removal of the liquid D to be dosed from a line under pressure. In this alternative, the control vessel 6 is filled with the aid of a liquid switch 150 which is connected to the control unit 130 by means of a control line 151. The liquid switch 150 has an output 152 which is connected to the feed pipe 100, an input 153. with the line under pressure is diluted with the liquid D and the outlet 154 which opens into the drain 155. 1, the reservoir 3, the compressed air line 9 and the outlet 802 of the air distributor 8 are omitted. Except for the filling of the control vessel 6 by means of an overpressure of the compressed air source 7, the dosing device works identically as that Dosing device according to FIG. 1. The control vessel 6 or the entire metering device is filled directly from the pressure line via the liquid urea switch 150 if the control unit 130 controls the changeover switch 150 via the control line 151 such that the path between the input 153 and the output 152 is open. This path remains open until the filling process has ended and the level of the regulated liquid level 61 has been reached. The control unit 130 then, after the excitation by level sensor 110, issues a control command to the liquid switch 150 such that the path from the outlet 152 to the outlet 154 is now open and the liquid D can be removed from the metering device. After the automatic stabilization of the internal liquid level, as described, the dosing device according to FIG. 3 works absolutely identical to the dosing device according to FIG. 1 .

FIG. 4 shows a modified reservoir 3 which allows the liquid D to be dosed to be removed from a flow channel or from a larger container 36. The reservoir 3 has an opening 35 in its bottom, which prevents the penetration of the liquid D to be dosed allows in the reservoir 3. The opening 35 is dimensioned and the immersion depth of the reservoir 3 is selected such that a perfect function when filling the metering device, as described above, is ensured.

FIG. 5 shows a variant of the modified reservoir 3 according to FIG. 4, in which a check valve (flap) 37 is used instead of the opening 35.

In FIGS. 6 and 7, the air distributor consists of a stator with a reference channel 800 and symmetrically arranged outputs 801 to 811. In the distribution space 8251 of the stator 825, which is open to the free atmosphere, a rotatingly movable distribution nozzle 812 is arranged.

The distributor nozzle 812 is connected in the clutch space 8253 of the stator 825 by means of a clutch 141 to the shaft 142 of the drive 140. Drive 140 is mechanically connected to stator 825 by fasteners 826.

The reference channel 800 is connected to the indicator of the reference position 814 with the aid of the connecting tube 813. The outputs 801 to 811 of the air distributor 8 are connected to the locations where the compressed air to be distributed is required.

The distribution nozzle 812 has a through-channel 8122 with the inlet opening 8123 and the mouth 8121. The cavity 8252 is connected to the compressed air source 7 via the outlet 815 of the air distributor 8 and via the feed line 71. The inlet opening 8123 of the rotating movable distribution nozzle 812 and the cavity 8252 are sealed off from the other spaces of the stator 825 with the seals 824. The mouth 8121 of the distribution nozzle 812 is arranged such that the centers of the openings of the reference channel 800 and the outputs 801 to 811 of the air distributor 8 are in the same plane as the axis through the center of the mouth 8121 perpendicular to the axis of rotation 8124 of the distribution nozzle 812. The distance X between the surface of the distribution space 8251 and the mouth 8121 of the distribution nozzle 812 is given by the permitted pressure loss, the flow rate and the amount of compressed air.

The reference position indicator 814 e.g. in the form of a pressure sensor or microphone, a signal leads to the control unit 130 by means of a signal line 135. The control unit 130 controls the drive 140 via the control line 132 and the compressed air source 7 via the control line 133. The function of the control unit 130 can be determined via the control input 136 by any higher-level devices.

FIG. 8 shows a variant of the distributor in the embodiment with a distributor nozzle 812 which moves in a straight line. In this variant, the drive 140 is designed such that the shaft 142 executes a straight movement. The surface of the stator 825 facing the distribution nozzle 812 is flat in this case. The opening of the reference channel 800, the outputs 801 to 811 of the air distributor 8 and the mouth 8121 the distribution nozzle 812 are at an int distance from one another. In this case, the distribution nozzle 812 is connected directly to the compressed air source 7 by means of a flexible feed line 71.

FIG. 9 shows a possible embodiment of the distribution nozzle 812 and the outputs 801 to 811 of the air distributor 8 with conical openings.

The distributor in the version according to FIGS. 6 and 7 works as follows:

When the distributor is switched on or as required, the drive 140 and the compressed air source 7 are switched on. In this start-up cycle, the compressed air source 7 is controlled in such a way that it only delivers an air pressure that just causes the indicator of the reference position 814 to respond reliably and is without consequence to the points to be connected to the outputs 801 to 811 of the air distributor 8. After switching on, the distribution nozzle 812 is set in motion via the shaft 142 and the clutch 141. When the mouth 8121 of the distribution nozzle 812 reaches the position of the opening of the reference channel 800 and the indicator of the reference position 814 detects the pressure signal. a signal is output by the latter via the signal line 135 to the control unit 130. The control unit 130 thus ensures that the drive 140 is maintained in such a way that the mouth 8121 of the distribution nozzle 812 remains in relation to the opening of the reference channel 800, at the same time the compressed air source 7 is then also switched off. By This start-up cycle defines the clear starting point for further function of the distributor. The desired distribution takes place as follows: First, the distribution nozzle 812 is positioned to the corresponding outlet 8ol to 811 of the air distributor 8 by moving the drive 140, which contains the control commands via the control line 132 from the control unit 130. Only after the desired position has been reached, the compressed air source 7 is switched on by the control unit 130 via the control line 133 and the compressed air supply specified by the control unit 130 begins in one of the outputs 801 to 811 of the air distributor 8. The remaining outputs of the air distributor 8 are connected to the free atmosphere.

The distributor in the embodiment according to FIG. 8 works identically to the embodiment described above according to FIGS. 6 and 7, with the difference that the distributor nozzle 812 performs a linear movement instead of a rotating one.

The embodiment of the distributor nozzle 812 of the reference channel 800 and the outputs 801 to 811 of the air distributor 8 shown in FIG. 9 works according to the ejector principle. In this variant, the known suction effect occurs, which counteracts the loss of the medium to be distributed. The level transmitter described in the examples can work on the various principles such as B. with float, photoelectric, on the principle of electrical conductivity, capacitance, a determination of the dielectric constant, with thermistor, etc.

The compressed air source can work according to any principle, it just has to be controllable.

The examples described above show the versions with a reference duct and eleven outputs of the air distributor. Versions with any number of channels are possible.

The indicator of the reference position of the air distributor can also work on another principle, such as photoelectric, magnetic, mechanical, etc.

The air distributor described can be designed with valves, flaps, cams, slides etc. or as a motorized air distributor.

A stepping motor and also all known drives can be used for the movement of the distributor nozzle of the air distributor, but they have to provide a feedback of their shaft position to the control unit.

The dosing device according to the invention has the property that the internal liquid levels are set automatically and independently, which means one of the liquids amount in the reservoir and accurate dosage independent of the level fluctuations is possible.

Due to the type of filling and the construction of the dosing vessel, the formation of air bubbles is prevented and thus an exact dosing of the smallest quantities is possible.

The dosing device works reliably after the first switch-on without the need to manually fill the inner parts.

The reservoir of the liquid to be dosed is arranged below the dosing device and can therefore have larger dimensions.

The liquid level of the reservoir can be automatically monitored by simple air pressure measurement during each dosing cycle.

The dosing device also enables dosing of liquids from large containers, flow channels and pressurized lines.

The device according to the invention is used in chemistry and related fields, in the construction of various apparatus, chemical analyzers, filling machines, etc.

Claims

Claims

1.Device for dosing liquids, of which a liquid is released by a pneumatic action, characterized in that a dosing tube (1) with a dosing vessel (14), which lies in a filling vessel (15), has an inflow opening in its upper part (16) and a ventilation pipe (17) and that the filling vessel (15) is connected at the very bottom by means of an inflow pipe (2) to a regulation vessel (6) with a regulated liquid level (61), with a level sensor (110) of the regulated liquid level (61) which is housed in the control vessel (6) and via a signal line (111), a transmitter (120) and. a line (131) is connected to a control unit (130), the control unit (130) being connected via a control line (133) to a compressed air source (7), this compressed air source (7) via a feed line (71), an air distributor (8), an air pressure line (9) is connected to a reservoir (3) which opens into the control vessel (6) with a feed pipe (100), the control unit (130) also having a drive (132) with a drive ( 140), the drive (140) being connected by means of a coupling (141) to the distribution nozzle (812) of the air distributor (8), the air distributor (8) opening into the free atmosphere with its outlet (801) Output (802) is connected to the compressed air line (9) and its output (803) is connected to a connecting pipe (4) which is connected with its branch (42) to an immersion pipe (51) of an overpressure regulator (5) and with its branch (41) connected to the filling vessel (15) is outside.

2.Device for dosing liquids according to claim 1, characterized in that in a filling vessel (15) is a dosing vessel (14) with the upper part fully open, the upper part of the dosing vessel (14) simultaneously the vent pipe (17) and forms the inflow opening (16), this upper part of the metering vessel (14) being below the regulated liquid level (61).

3.Device for dosing liquids according to claim 1 and 2, characterized in that a level transmitter (110) is housed in a filling vessel (15), a feed pipe (100) leading to a reservoir (3) with a Overflow (62) is equipped and its upper part (101) opens into the free atmosphere, an inflow pipe (2) being connected to the feed pipe (100).

4.Device for dosing liquids according to claims 1 to 3 characterized in that a reservoir (3), which is placed in a flow channel or in a container (36), has an opening (35) or a check valve or flap (37) .

5.Device for dosing liquids according to claim 1 to 4, characterized in that a pressure indicator (72) is connected to the feed line (71) and is connected to the control unit (130) via a signal line (134).

6. Device for dosing liquids according to claim 1 to 3, characterized in that. The feed pipe (100) is connected to a liquid changeover switch (150) which is connected to the control unit (130) via a control line (151).

7.Device for dosing liquids according to claims 1 to 6, characterized in that a wiping nozzle (812) of an air distributor (8) with an inlet opening (8123), a through-channel (8122) and an orifice (8121) which is movable in one Stator (825), which contains a reference channel (800) and outputs (801 to 811), is accommodated in such a way that the mouth (8121) of the distribution nozzle (812) is at a distance (X) from the surface of a distribution space (8251) Is stator (825), the distributor nozzle (812) being connected to a compressed air source (7) via a sealed cavity (8252) of the stator (825) and a feed line (71), the distributor nozzle (812) being connected by means of a coupling (141 ) is connected to a shaft (142) of a drive (140) which is controlled by a control unit (130), the control unit (130) also controlling the compressed air source (7).

8. Device for dosing liquids after

Claims 1 to 6, characterized in that a rectilinearly moving distributor nozzle (812) of an air distributor (8) with an inlet opening (8123), a through-channel (8122) and an orifice (8121), which is movable against a stator (825) contains a reference channel (800) and exits (801 to 811), so that the mouth (8121) of the distributor nozzle (812) is at a distance (X) from the stator (825), the distributor nozzle (812) Connected to a compressed air source (7) via a flexible feed line (71), the distribution nozzle (812) being connected to a shaft (142) of a drive (140) controlled by a control unit (130) by means of a coupling (14L) the control unit (130) also controls the compressed air source (7).

9. Device for dosing liquids after

Claims 1 to 8, characterized in that an air distributor (8) is connected to a reference channel (800) via an indicator of the reference position (814) and a signal line (135) to a control unit (130).

10. A device for dosing liquids according to claims 1 to 9, characterized in that a distributor nozzle (812) is connected by means of a coupling (141) to a shaft (142) of a drive (eg the stepping motor) (140), which is a feedback device its shaft position, which is connected to a control unit (130).

11. A device for dosing liquids according to claim 1 to 10, characterized in that a distributor nozzle (812) of an air distributor (8) with a mouth (8121) and outputs (801 to 811) of the air distributor (8) are constructed and arranged in this way that they form ejectors.